The Energy Revolution has begun and will change your lifestyle

Welcome to the Energy Blog

The Energy Blog is where all topics relating to The Energy Revolution are presented. Increasingly, expensive oil, coal and global warming are causing an energy revolution by requiring fossil fuels to be supplemented by alternative energy sources and by requiring changes in lifestyle. Please contact me with your comments and questions. Further Information about me can be found HERE.

Statistics

February 19, 2006

SolFocus-PARC Collaborate on Concentrator PV

SolFocus Inc., a spinoff from H2Go in 2004, and Xerox's Palo Alto Research Center (PARC) on February 16 announced a research collaboration to develop solar Concentrator PV (CPV) systems. The broad agreement is to jointly develop CPV systems that can deliver low-cost, reliable solar energy. SolFocus CPV solutions can potentially:

advance the market beyond current flat-plate silicon PV and it underlying cost limitations;

deliver both short- and long-term cost advantages which is the critical metric of market success;

position CPV to be competitive with conventional electricity; and

open large new markets for clean solar energy

The venture builds on the original SolFocus design for concentrator photovoltaic technology (shown left). CPV technology creates electricity by using precision optical components such as lenses and mirrors to direct and “concentrate” sunlight onto high-efficiency solar cells. SolFocus’s prototype solar panels are smaller, cheaper, and easier to manufacture than the flat-plate photovoltaic panels that currently dominate the market.

CPV systems use relatively inexpensive optics such as mirrors or lenses to “concentrate” or focus light from a relatively broad collection area onto a much smaller area of active semiconductor PV cell material. Since the silicon in solar cells usually dominates the costs of the solar PV system, reducing the amount of silicon leads to substantially lower system cost and resulting cost per watt of output.

For higher concentrations that reduce silicon use by 100-1000 times more, it is cost-effective to use higher efficiency cells that increase the electricity generated from a given collection area—even though this PV material can cost up to ten times more than silicon.

Up to 2 MW (megawatts) of the Gen 1 design will be installed in 2006-2007 at pilot sites in California, Hawaii, and Shanghai, China.

The Gen 2 design, which further improves performance and reduces costs at higher volume production, will be available for test installations a couple of years later.

Both modules are targeted for rooftop- and field-installed solar systems.

Advantages Compared to Flat-plate PV

Requires only 1/1000th of the expensive, active semiconductor material as other PV systems to generate the same amount of electricity from the sunlight falling on a given area

Lowers the cost of solar electricity to less than half what is available today

Operates at nearly double the efficiency of most flat-plate PV

Both CPV Modules

Enabled by highest-efficiency cells available—Spectrolab (division of Boeing) triple-junction cells approaching 40% at over 500-sun concentration. 1 cm2 cells are used in Gen1 and1 mm2cells are used in Gen2.

Gary Conley, SolFocus chief executive officer, said, 'The first-generation panels will break price barriers in the market, but the second-generation panels with PARC technology will change the market for solar dramatically. The current installed cost of the flat-plate photovoltaic systems is about $7 per watt, but our approach should produce electricity for about half that amount – or less.”

During 2005, a total of six prototypes, of varying configurations between 500 and 2,000 Watts peak, were designed and are in the final stages of development and production. H2Go will install these first systems at various research sites to gain the best possible performance knowledge in the shortest period of time, and by calling upon extraordinary people with unique skills. The Gen1 products are in pilot production. First-generation SolFocus CPV prototypes were installed at PARC in January 2006. Up to 2 MW of the Gen1 design will be installed in 2006-2007 at pilot sites in California, Hawaii, and Shanghai, China.

Gen 2 CPV Module

The Gen2 design further improves performance, scalability and durability as well as reducing costs. The module design is based on a solid-state, or “one-piece,” concept featuring small reflective concentrator elements housed in a flat molded glass tile with mirrors on each side. The Gen2 module will be available for test installations in 3 or 4 years.

Each tile will contain 160 individual cells, generating a total of 30 watts of electricity, 285W/m2. Several tiles can be joined together to deliver the desired electrical output. Initially the tiles will be made with stamped glass, but as production volumes increase a rolled process will be used. The 11 x 17 inch (280 x 430 mm) tiles have an average thickness of 0.16 inches (4 mm). Early Gen2 modules are undergoing test.

The CPV systems will be produced for business, not residential applications. They are targeting large rooftop systems such as shopping malls, warehouses, factories and big box stores as well as field mounting for solar power plants.

The target installed cost for systems in high volume production is $1.00/W. The cost of goods sold (COGS) is projected to reach $0.55/W for Gen1 modules and $0.35/W for Gen2 modules at a 1GW per year production rate. They plan on selling about 2 MW of Gen1 modules to early adopters at approximately $5.00/W. SolFocus expects revenues in the next 18-24 months of $30 million to take them through to profitability. They have about $10 million in pending orders. SolFocus is in the process of hiring contract manufacturers in China.

CPV development at H2Go has depended upon collaborative efforts from the beginning. Early contributions in non-imaging optical design came from researchers at the University of California at Merced, who continue to contribute to optical design, system tests, automation, cost reduction and lifecycle/reliability.

Ben Gurion University in Israel developed the extremely compact compound non-imaging optical design which is employed in first generation systems and they continues to address projects in cell performance, endurance and optical nano-coatings.

Under the new agreement with PARC, it is contributing core patents and long-term technology development support for current and next-generation product lines in exchange for royalties and equity in SolFocus.

SolFocus is contributing H2Go's patents pending on the Gen1 design and optics, the Gen2 design and two more patents to be filed. SolFocus will hold all foreword intellectual property.

SolFocus competitors are Sunball which produces modules for relatively small installations, usually under 10kW; Sunflower, IAS, and Amonix produce larger modules which compete more directly with SolFocus. All use plastic Fresnel lenses in their designs which Solfocus claims have inferior optics and are less durable than their glass mirrors. The competitors have the advantage in that they are all in production with a track record being established.

Comments

The formatting for the section starting with the bullets in the Gen 2 section and going to the "SolFocus competitors are Sunball..." line is way right indented and most of it is off the screen, at least on my browser.

I was under the impression that the big challenge in solar collectors was not the cost of the collector array, but of the tracking hardware. I didn't see a mention in the article regarding whether they have addressed this problem.

I still believe the tech with the highest potential is in solid state systems, like holographic mirrors and lenses, which have no need to track the sun. One variation I found very interesting was a film that would redirect sunlight incident on a window at certain angles (think: 5pm or noonday sun glaring through the window) toward the ceiling. The biggest downside is that current prices dwarf that of tracking systems.

I don't have any formating problems that I can see when I view my blog. Anyone else having a problem?

As far as the tracking hardware, their only mention was "there have been a number of cost and reliability improvements, and trackers are commonly used in large field-based installations of even flat-plate PV....However, improved system features including lightweight trackers and recent technological advancements are allowing CPV to be mounted on rooftops where it can generate 10-100 kilowatts of electricity at many commercial sites or 1 MW or more on large industrial rooftops."

They havn't had much field experience, so it is too early to tell if they are having problems. They claim to have run reliability tests on all equipment, but from the context of that statement it is hard to tell if that was for modules or for the whole system.

I'm having the format problems too (viewing with Firefox).
This kind of idea seems a likely way forward to me. I'd previously wondered whether it would be possible to have cheap glass 'light-catchers' that sent most daylight via optic cables to a combined in-house PV unit. That way as much light as is available could be relatively easily captured and the light-electricity unit could be upgraded as more-efficient PV materials are created. Such a system would have the added advantage of being able to transfer light directly to luminaires (increasing efficiency).
The lack of sunlight in countries such as mine (U.K) could also be countered by the purchase of more fairly cheap, entirely glass panels. God knows I don't know how solar is ever going to be part of the mix here otherwise!

Nick is right and I have changed the text to indicate this. There are just too many details that my old mind has trouble remembering and I really don't have time to check everything out. Thanks for keeping me honest.

It's a giant leap to say that Sunflower, IAS and Sunball are in production and way ahead of Solfucus. (Amonix, on the other hand, has been a major player for many years and is in production.) All are still in the testing stage and are, at best, in pre-production stage.

It seems to me that dealing with all the excess heat on the cells would be an opportunity to heat some hot water for the building as well. Heat the water, cool the cells and the costs can be defrayed even more, as well as increasing the life of the cells.